DE102019114919A1 - Method for regulating a fuel gas operated heater - Google Patents

Abstract

The invention relates to a gas type-independent method for regulating a fuel gas-operated heater using an ionization measurement method of a burner flame of the heater and a gas control characteristic curve of the gas control element.

Description

The invention relates to a method for regulating a fuel gas-operated heater.

Generic methods are known from the prior art, for example from the disclosure according to the publication WO2006 / 000366A1 . A person skilled in the art is also familiar with combustion control according to the so-called SCOT method, in which the amount of air supplied to the burner of the heater is controlled in accordance with the burner output. A flame signal measurement is carried out by means of an ionization sensor and the gas-air mixture is regulated to a target ionization measurement value stored in a characteristic curve. The disadvantage of the SCOT process, however, is that the flame signal drops sharply at low burner outputs, making the control unreliable. In addition, the adaptation effort, in particular for adapting the burner geometry, is high and the burner output can only be determined imprecisely via the fan speed of a fan supplying the air volume flow for the gas-air mixture.

Another problem with the control method is that different types of gas, e.g. Natural gas or liquid gas, as well as gas qualities, are used. The parameters of the control process must be adapted to the type of gas or gas quality, as otherwise the combustion will be unclean.

Alternative control methods are based on an electronic mixture control using thermal gas mass sensors to record the fuel gas properties via the thermal conductivity of the fuel gas. The air requirement is determined from the type of fuel gas using a reference table and the air volume is calculated and adjusted according to the measured gas volume and the determined air requirement. However, the method requires that all input variables required for the mixture control must be measured and monitored.

The invention is based on the object of providing a method, which is independent of the type of fuel gas, for regulating a fuel gas-operated heating device over a broad modulation range, which method requires less monitoring effort and hardware use than the known methods. In particular, it should be possible to dispense with the use of a fuel gas mass sensor.

This object is achieved by the combination of features according to patent claim 1.

According to the invention, a method for regulating a fuel gas-operated heater using an ionization measurement method of a burner flame of the heater is proposed, in which a fuel gas volume flow controlled by a gas actuator and an air volume flow supplied by a fan are mixed to form a fuel gas-air mixture and with an air ratio λ based on a desired burner output be fed to a burner of the heater. The air ratio λ is monitored by means of the ionization measurement method of the burner flame of the burner. In addition, a gas control characteristic curve of the gas control element is recorded in the laboratory and stored in a control unit. The gas actuator control characteristic here determines a percentage flow rate through the gas actuator depending on the opening position points of the gas actuator, the percentage flow rate through the gas actuator representing a burner output of the burner. The burner output of the burner is regulated in a first output range based on the results of the ionization measurement process and in a second output range based on the gas actuator control characteristic, with certain burner outputs being assigned to certain opening positions of the gas actuator during the regulation of the heater in the first output range. The ratio of the amount of fuel gas to the amount of air is kept constant in the second power range.

The first power range preferably corresponds to a control range in which the burner flame supplies the ionization measurement method with sufficiently accurate signal data that the control can take place as a pure ionization control. This is the case in particular with a sufficiently large burner flame in which the ionization electrode used for the ionization measurement method supplies exact signals to the control device. The second power range is in particular a range of low burner power, for example below 50% of the maximum power.

The gas actuator control characteristic is predefined in the laboratory. The gas actuator control characteristic includes any number of subdivision points that correspond to the positions of the gas actuator for fixed burner output steps. This also defines the relationship between the amount of fuel gas and the respective opening position of the gas actuator. With the same burner output, ie the heating output of the heater, there are different working ranges in the characteristic curve depending on the type of fuel gas due to the different density of the fuel gas, the different energy content and air requirement. When the gas quality changes, e.g. B. from LPG to natural gas would be due to the changed density of volume flow change. The energy content and thus the amount of fuel gas required to achieve the desired burner output would also be different. Since these relationships apply to each of the controlled positions, the absolute burner output changes, but not the ratio of the individual opening positions of the gas actuator to one another. If, for example, the actual burner output is halved in one opening position, then the burner output is halved in all other output points along the control characteristic. According to the invention, a gas actuator control characteristic is thus used which determines a percentage flow rate through the gas actuator as a function of the opening position points of the gas actuator.

The method provides that the specific outputs of the burner are assigned to the specific opening position points of the gas actuator by measuring a quantity of air supplied to the burner at any opening position during the regulation of the burner output of the burner in the first power range and supplying a required quantity of fuel gas via the gas actuator is until a predetermined air ratio λ is reached. In addition, the required burner output is changed by adapting the air quantity, with the control device setting corresponding opening positions of the gas actuator from the gas control characteristic curve of the adjusted burner output.

The disclosed method makes use of the fact that the burner output is known during the regulation in the first regulation range using the ionization measurement method, and from this the opening position points of the gas actuator can be predetermined for all other desired burner outputs. For this purpose, the air volume flow for generating the fuel gas-air mixture is measured during the control in the first control range using the ionization measurement method in any opening position of the gas actuator. The control device regulates the amount of fuel gas required for clean combustion of a predefined air ratio via the ionization control. The matching opening position of the gas actuator is assigned to the corresponding air volume flow in the control unit. If the heat demand falls or increases, if a new air volume is set via the control unit via the fan, for example 10% less or more, then the appropriate fuel gas volume must also be adjusted as a percentage, i.e. also 10% less or more. This adaptation takes place via a change in the opening position of the gas actuator controlled by the control unit.

A further development of the method provides that the gas actuator control characteristic is calibrated at time intervals to compensate for a characteristic drift. A characteristic drift is characterized by a change in the amount of fuel gas that occurs over the service life at certain opening positions of the gas actuator.

In the case of a characteristic drift, the individual opening position points no longer correspond to the corresponding fuel gas volume flows, but the percentage power differences between the individual opening position points remain constant because the flow characteristics through the gas actuator do not change due to the characteristic drift. This means that the characteristic curve itself does not change, only the position within the working area. The characteristic drift can be equalized by calibration.

In one embodiment, the calibration takes place during the regulation of the burner output of the burner in the first output range based on the results of the ionization measurement process, in that two output points of the burner output are controlled via the control unit and the output values of the burner output stored in the gas actuator control characteristic are compared with the actual output values of the burner output the gas actuator control characteristic is corrected to the actual output values of the burner output.

An advantageous embodiment of the method further provides that the gas actuator is controlled by a stepping motor and a defined number of steps of the stepping motor determines a defined change in the opening position points of the gas actuator.

• 1 einen schematischen Aufbau eines Heizgerätes;
• 2 eine im Verfahren genutzte Gasstellglied-Regelungskennlinie,
• 3 die Gasstellglied-Regelungskennlinie aus 2 für Erdgas, 4 die Gasstellglied-Regelungskennlinie aus 2 für Flüssiggas,
• 5 einen Kennliniendrift der Gasstellglied-Regelungskennlinie aus 2, und
• 6 eine Kalibrierung des Kennliniendrifts der Gasstellglied-Regelungskennlinie aus 2.

Other advantageous developments of the invention are characterized in the subclaims or are shown in more detail below together with the description of the preferred embodiment of the invention with reference to the figures. Show it:

• 1 a schematic structure of a heater;
• 2 a gas actuator control characteristic used in the process,
• 3 the gas actuator control characteristic 2 for natural gas, 4th the gas actuator control characteristic 2 for liquid gas,
• 5 a characteristic drift of the gas actuator control characteristic 2 , and
• 6th a calibration of the characteristic drift of the gas actuator control characteristic 2 .

In 1 Fig. 3 is a schematic structure of a heater 100 to carry out the control process with a modulating premix fan 5 , which sucks in ambient air and mixes it with fuel gas. The fuel gas is fed to the premix fan 5 at the entrance 4th Supplied via a gas line in which a gas safety valve 1 and a gas valve that can be controlled by a motor M, for example 2 are arranged, which forms the gas actuator. The gas inlet pressure d is set to the gas control pressure c customized. After mixing with ambient air, the mixture has the mixture pressure b on. In the version shown, there is an optional non-return valve at the blower outlet 6th intended. The mixture then has the burner pressure e. This is followed by the burner 28 with the ionization electrode arranged in the burner flame 7th . Around the burner 28 is the heat exchanger 18th arranged. Continued in the direction of flow, the exhaust system with the exhaust flap follows 8th . The exhaust pressure f prevails in the exhaust system. The control of the amount of fuel gas as well as the fan speed and therefore the air ratio takes place via the control unit 9 , in which the control characteristics are stored.

2 shows the gas actuator control characteristic used for the method 82 with opening position points p1, p2, p3 - p9, which is a defined opening position of the gas valve 2 and therefore represent a fixed percentage flow rate F of fuel gas.

The regulation of the burner output of the burner 28 takes place in the power range in which the ionization control is sufficiently precise, based on the results of the ionization measurement method using the ionization electrode 7th . The gas actuator control characteristic 82 of the gas valve 2 is recorded in the laboratory and in the control unit 9 deposited. It is used for the process in a power range in which the ionization control is based on the ionization measurement via the ionization electrode 7th is not sufficiently accurate. Thereby are during the regulation of the heater 100 in the power range of the ionization control certain opening position points p of the gas actuator, certain outputs of the burner 28 assigned. The ratio of the amount of fuel gas to the amount of air remains in the control using the gas actuator control characteristic 82 constant. The opening position points p of the gas valve 2 are certain outputs of the burner 28 assigned by regulating the burner output of the burner 28 in the power range of the ionization control at any opening position p of the burner 28 the amount of air supplied, the required amount of fuel gas via the gas valve 2 is supplied until the desired air ratio λ is reached. The required burner output is changed by adjusting the amount of air, using the control unit 9 from the gas actuator control characteristic 82 opening position points p of the gas valve corresponding to the adjusted burner output 2 can be set.

The 3 and 4th show the gas actuator control characteristic 2 for two different types of fuel gas, whereby 3 for example natural gas, 4th Corresponds to liquid gas. According to 3 a gas volume flow for, for example, 10 kW burner output is achieved in the opening position point p8, which corresponds to 80% of the control characteristic. Used by the control of the heater 100 For example, half the power of 5 kW is required, position p4 is activated by the controller, which corresponds to 40% of the control characteristic. If the fuel gas changes from natural gas to liquid gas, the burner output is 10kW at an opening position point p6 with the same burner output, half the burner output at p3, as in 4th shown. The control unit 9 can thus from each burner output established and verified once during the ionization control by adjusting the opening position points p of the gas valve 2 adapt or interpolate the burner output to the corresponding air flow.

In 5 is a characteristic drift of the gas actuator control characteristic 82 over the life of the heater 100 shown. It is preferred to control the gas valve 2 a stepper motor M is used. In the course of the service life, with the same number of steps of the stepper motor M, different fuel gas volume flows result. For the control, this means a shift in the control range and the opening position points p for the gas valve 2 from the original power range 86 to a new range of services 83 , as in 5 shown. For calibration of the gas actuator control characteristic 82 and equalization of the characteristic drift are according to the disclosure of 6th In the area of the ionization control, two power points with, for example, opening position points p9 and p6 are controlled, which 90% and 60% of the burner output of the burner 28 determine. From a comparison of the controlled positions with those in the control unit 9 stored positions, a difference in the step change of the stepping motor M as well as a possible change in power is determined, which in 6th are shown by way of example as Δ9 and Δ6. A new characteristic curve position is determined from the shifts of the two performance points and all new opening position points p are corrected. 6th shows that at an exemplary Power of 10% from the step difference of the stepper motor M between the old one in the control unit 9 A new step difference, marked as Δ1-6, is calculated for the stored credit point 60% to 10%. The calibrated characteristic is then replaced in the control unit 9 the previous characteristic.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• WO 2006/000366 A1 [0002]

Claims (6)

Method for regulating a fuel gas-operated heater (100) using an ionization measurement method of a burner flame of the heater, wherein a. a fuel gas volume flow controlled by a gas actuator and an air volume flow supplied by a fan are mixed to form a fuel gas-air mixture and fed to a burner (28) of the heater with an air ratio λ based on a desired burner output, b. the air ratio λ is monitored by means of the ionization measurement method of the burner flame of the burner (28), c. a gas actuator control characteristic (82) of the gas actuator is recorded in the laboratory and stored in a control unit (9), the gas actuator control characteristic (82) determining a percentage flow rate through the gas actuator as a function of an opening position point (P) of the gas actuator, the percentage The flow rate through the gas control element represents a burner output of the burner, d. the regulation of a burner output of the burner in a first output range based on the results of the ionization measurement method and in a second output range based on the gas actuator control characteristic (82) takes place, with certain opening positions (P) of the gas actuator being determined during the regulation of the heater in the first output range Performances of the burner are assigned, and wherein the ratio of the amount of fuel gas to the amount of air in the second power range is kept constant. Procedure according to Claim 1 , characterized in that the specific outputs of the burner are assigned to the specific opening position points (P) of the gas control element in that during the regulation of the burner output of the burner in the first output range at any opening position (P) an amount of air supplied to the burner (28) and a required amount of fuel gas is supplied via the gas actuator until a predetermined air ratio λ is reached. Procedure according to Claim 1 or 2 , characterized in that the required burner output is changed by adjusting the amount of air, and the opening position points (P) of the gas control element corresponding to the adjusted burner output are set via the control unit (9) from the gas actuator control characteristic (82). Method according to one of the preceding claims, characterized in that the gas actuator control characteristic (82) is calibrated at time intervals to compensate for a characteristic drift. Method according to the preceding claim, characterized in that the calibration takes place during the regulation of the burner output of the burner (28) in the first output range based on the results of the ionization measurement process, in that two output points of the burner output and those of the gas actuator are controlled via the control device (9) Control characteristic curve (82) stored power values of the burner output are compared with the actual output values of the burner output, the gas actuator control characteristic curve (82) being corrected to the actual output values of the burner output. Method according to one of the preceding claims, characterized in that the gas actuator is controlled by a stepping motor (M) and a defined number of steps of the stepping motor (M) determines a defined change in the opening position points (P) of the gas actuator.

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